ASMT-JN32-NVVG1 - Avago Technologies

ASMT-Jx32

3W Mini Power LED Light Source

Data Sheet

Description

The 3W Mini Power LED Light Source is a high perfor-

mance energy ecient device which can handle high

thermal and high driving current. The metal slug is electri-

cally isolated.

The White Mini Power LED is available in the range of color

temperature from 2700K to 10000K.

The low prole package design and ultra small footprint is

suitable for a wide variety of applications especially where

space and height is a constraint.

The package is compatible with reow soldering process.

To facilitate easy pick & place assembly, the LEDs are

packed in EIA-compliant tape and reel.

Features

• Available in Cool White, Neutral White and Warm White

• Small footprint and low prole

• Symmetrical outline

• Energy ecient

• Direct heat transfer from metal slug to mother board

• Compatible with reow soldering process

• High current operation

• Long operation life

• Wide viewing angle

• Silicone encapsulation

• Non-ESD sensitive (threshold > 16kV)

• MSL 1 products

Applications

• Sign backlight

• Safety, exit and emergency sign lightings

• Specialty lighting such as task lighting and reading lights

• Retail display

• Commercial lighting

• Accent or marker lightings, strip or step lightings

• Portable lightings, bicycle head lamp, torch lights

• Decorative lighting

• Architectural lighting

• Pathway lighting

• Street lighting

• Pedestrian street lighting

• Tunnel lighting

CAUTION: Customer is advised to keep the LEDs in the MBB when not in use as prolonged exposure to

environment might cause the silver plated leads to tarnish, which might cause diculties in soldering.

Package Dimensions

Notes:

1. All dimensions in millimeters.

2. Tolerance is ±0.1 mm unless otherwise specied.

3. Terminal nish: Ag plating.

4. Corresponding NC (No Connection) leads adjacent to

anode and cathode leads can be electrically short.

Figure 1. ASMT-Jx32 package outline drawing

5.0

4.0

0.7

1.0

0.3

1.85

Ø 3.7

0.8

0.65

0.60

Ø 1.70

Body Cathode Lead

Lens

Cathode Mark

Anode Lead NC

Metal Slug

Part Numbering System

Device Selection Guide (TJ = 25°C)



Part Number



Color

Luminous Flux (Im), ΦV[1,2]

Test Current

(mA)

Dice

Technology

Electrically

Isolated

Metal Slug Min. Typ. Max.

ASMT-JW32-NUV01 Cool White 87.4 100.0 113.6 350 InGaN Yes

ASMT-JW32-NVV01 99.6 105.0 113.6 350 InGaN Yes

ASMT-JW32-NVW01 99.6 110.0 129.5 350 InGaN Yes

ASMT-JW32-NWX01 113.6 125.0 147.7 350 InGaN Yes

ASMT-JN32-NUV01 Neutral White 87.4 100.0 113.6 350 InGaN Yes

ASMT-JN32-NVV01 99.6 105.0 113.6 350 InGaN Yes

ASMT-JN32-NVW01 99.6 110.0 129.5 350 InGaN Yes

ASMT-JN32-NWX01 113.6 125.0 147.7 350 InGaN Yes

ASMT-JY32-NTV01 Warm White 67.2 90.0 113.6 350 InGaN Yes

ASMT-JY32-NUW01 87.4 105.0 129.5 350 InGaN Yes

Notes:

1. ΦV is the total luminous ux output as measured with an integrating sphere at 25ms mono pulse condition.

2. Flux tolerance is ±10%

Absolute Maximum Ratings

Parameter ASMT-Jx32 Units

DC Forward Current [1] 700 mA

Peak Pulsing Current 2400 mA

Power Dissipation 2730 mW

LED Junction Temperature 135 °C

Operating Metal Slug Temperature Range at 350 mA -40 to +120 °C

Operating Metal Slug Temperature Range at 700 mA -40 to +105 °C

Storage Temperature Range -40 to + 120 °C

Soldering Temperature Refer to Figure 15

Reverse Voltage [2] Not recommended

Notes:

1. Derate linearly based on Figure 11.

2. Not designed for reverse bias operation.

ASMT- J x1 3 2 – x2 x3 x4 x5 x6

Packaging Option

Color Bin Selection

Maximum Flux Bin Selection

Minimum Flux Bin Selection

Dice Type

N – InGaN

Color

W – Cool White

N – Neutral White

Y – Warm White

Note:

1. Please refer to Page 8 for selection details.

Optical Characteristics at 350 mA (TJ = 25°C)

Part Number Color

Correlated Color Temperature,

CCT (Kelvin)

Viewing Angle,

2θ½ [1] (°)

Luminous Eciency

(lm/W)

Min. Max. Typ. Typ.

ASMT-JW32-NUV01 Cool White 4500 10000 140 89

ASMT-JW32-NVV01 4500 10000 140 94

ASMT-JW32-NVW01 4500 10000 140 98

ASMT-JW32-NWX01 4500 10000 140 112

ASMT-JN32-NUV01 Neutral White 3500 4500 140 89

ASMT-JN32-NVV01 3500 4500 140 94

ASMT-JN32-NVW01 3500 4500 140 98

ASMT-JN32-NWX01 3500 4500 140 112

ASMT-JY32-NTV01 Warm White 2700 3500 140 80

ASMT-JY32-NUW01 2700 3500 140 94

Note:

1. θ½ is the o-axis angle where the luminous intensity is ½ the peak intensity.

Electrical Characteristic at 350 mA (TJ = 25°C)

Dice Type

Forward Voltage,

VF (Volts)

Thermal Resistance,

RθJMS(°C/W) [1]

Min. Typ Max. Typ.

InGaN 2.8 3.2 3.5 9

Note:

1. RθJMS is Thermal Resistance from LED junction to metal slug.

Optical and Electrical Characteristic at 700 mA (TJ = 25°C)

Part Number Color

Luminous Flux (lm),

φV

Forward Voltage,

VF (Volts)

Typ. Typ.

ASMT-JW32-NUV01 Cool White 175.0 3.6

ASMT-JW32-NVV01 180.0 3.6

ASMT-JW32-NVW01 187.0 3.6

ASMT-JW32-NWX01 213.0 3.6

ASMT-JN32-NUV01 Neutral White 175.0 3.6

ASMT-JN32-NVV01 180.0 3.6

ASMT-JN32-NVW01 187.0 3.6

ASMT-JN32-NWX01 213.0 3.6

ASMT-JY32-NTV01 Warm White 153.0 3.6

ASMT-JY32-NUW01 179 3.6

0.0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

380 430 480 530 580 630 680 730 780

WAVELENGTH - nm

RELATIVE INTENSITY

0.0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

380 430 480 530 580 630 680 730 780

WAVELENGTH - nm

RELATIVE INTENSITY

0.2

0.4

0.6

0.8

1.2

1.4

1.6

1.8

0 100 200 300 400 500 600 700

RELATIVE LUMINOUS FLUX

(NORMALIZED AT 350 mA)

MONO PULSE CURRENT - mA

WARM WHITE

COOL WHITE

100

150

200

250

300

350

400

450

500

550

600

650

700

0 0.5 1 1.5 2 2.5 3 3.5 4

FORWARD VOLTAGE - V

FORWARD CURRENT - mA

Figure 2. Relative Intensity vs. Wavelength for Cool White and Warm White Figure 3. Relative Intensity vs. Wavelength for Neutral White

Figure 4. Relative Luminous Flux vs. Mono Pulse Current Figure 5. Forward Current vs. Forward Voltage

Figure 6. Maximum pulse current vs. pulse duration

Derated based on TA = 25°C, RθJ-A = 30°C/W.

Figure 7. Maximum pulse current vs. pulse duration

Derated based on TA = 85°C, RθJ-A = 30°C/W.

0.00

0.20

0.40

0.60

0.80

1.00

1.20

1.40

1.60

1.80

2.00

2.20

2.40

2.60

2.80

3.00

0.00001 0.0001 0.001 0.01 0.1 1 10 100

tp - PULSE DURATION - sec

IP - PULSE CURRENT - A

D =

0.05

0.10

0.25

0.50

1.00

0.20

0.40

0.60

0.80

1.00

1.20

1.40

1.60

1.80

2.00

2.20

2.40

2.60

2.80

3.00

0.00001 0.0001 0.001 0.01 0.1 1 10 100

tp - PULSE DURATION - sec

IP - PULSE CURRENT - A

D =

0.05

0.10

0.25

0.50

D = tp

0.00

Figure 9. Relative Light Output vs. Junction Temperature Figure 10. Forward Voltage Shift vs. Junction Temperature

Figure 11. Maximum Forward Current vs. Ambient Temperature. Derated

based on TJMAX = 135°C, RθJ-A = 20°C/W, 25°C/W and 30°C/W

Figure 12. Maximum Forward Current vs. Metal Slug Temperature. Derated

based on TJMAX = 135°C, RθJ-MS = 9°C/W

Figure 8. Radiation Pattern for Cool White, Warm White and Neutral White

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

-90 -60 -30 0 30 60 90

NORMALIZED INTENSITY

ANGULAR DISPLACEMENT - DEGREES

FORWARD VOLTAGE SHIFT - V

(NORMALIZED AT 25°C)

0.0

10.0

20.0

30.0

40.0

50.0

60.0

70.0

80.0

90.0

100.0

110.0

120.0

-50 -25 0 25 50 75 100 125 150

RELATIVE LIGHT OUTPUT (%)

(NORMALIZED AT 25°C)

JUNCTION TEMPERATURE, T

- °C

-0.35

-0.30

-0.25

-0.20

-0.15

-0.10

-0.05

0.00

0.05

0.10

0.15

0.20

0.25

0.30

-50 -25 0 25 50 75 100 125 150

JUNCTION TEMPERATURE, T

- °C

100

200

300

400

500

600

700

800

0 20 40 60 80 100 120 140

AMBIENT TEMPERATURE, TA - °C

MAX ALLOWABLE DC CURRENT - mA

RθJ-A = 20°C/W

RθJ-A = 25°C/W

RθJ-A = 30°C/W

100

200

300

400

500

600

700

800

0 20 40 60 80 100 120 140

METAL SLUG TEMPERATURE, T

- °C

MAX ALLOWABLE DC CURRENT - mA

RθJ-MS = 9°C/W

Solder Pad

Slug Indepdent

0.80

0.85

1.75

1.32

ø1.90

3.50

5.20

Figure 14. Recommended pick and place nozzle tip. Inner diameter = 3.2 mm

(Acc. to J-STD-020C)

217°C

200°C

60 - 120 SEC.

6°C/SEC. MAX.

3°C/SEC. MAX.

150°C

255 - 260°C

100 SEC. MAX.

10 - 30 SEC.

TIME

TEMPERATURE

Figure 15. Recommended Reow Soldering Prole

Note:

For detail information on reow soldering of Avago surface mount LEDs, do refer to Avago Application Note AN1060 Surface Mounting SMT LED

Indicator Components.

ø3.2

Figure 13. Recommended soldering land pattern

Option Selection Details

ASMT-J x1 3 2 – x2 x3 x4 x5 x6

x3 – Minimum Flux Bin Selection

x4 – Maximum Flux Bin Selection

x5 – Color Bin Selection

x6 – Packaging Option

Flux Bin Limit [x3, x4]

Bin ID

Luminous Flux (lm) at 350 mA

Min. Max.

T 67.2 87.4

U 87.4 99.6

V 99.6 113.6

W 113.6 129.5

X 129.5 147.7

Cool White

Selection Bin ID

0 Full Distribution

E VM, UM, VN and UN

F WM, VM, WN and VN

G XM, WM, XN and WN

H UN, VN, U0 and V0

J WN, VN, W0 and V0

K XN, WN, X0 and W0

L V0, U0, VP and UP

M W0, V0, WP, VP and WQ

N X0, W0, XP, WP and WQ

P Y0

Q YA

Warm White

Selection Bin ID

0 Full Distribution

E NM, MM, N1 and M1

F PM, NM, P1 and N1

G QM, PM, Q1 and P1

H M1, N1, M0 and N0

J P1, N1, P0 and N0

K Q1, P1, Q0 and P0

L N0, M0, NA and MA

M P0, N0, PA and NA

N Q0, P0, QA and PA

Neutral White

Selection Bin ID

0 Full Distribution

E SM, RM, S1 and R1

F TM, SM, TN and S1

G S1, R1, S0 and R0

H TN, S1, T0 and S0

J S0, R0, SA and RA

K T0, S0, TP and SA

Color Bin Selection [x5]

Individual reel will contain parts from one color bin selection only.

0.26

0.28

0.30

0.32

0.34

0.36

0.38

0.40

0.42

0.26 0.28 0.30 0.32 0.34 0.36 0.38 0.40

X-COORDINATE

Y-COORDINATE

10000K

7000K

6300K

5000K

4500K

XN W0

0.32

0.34

0.36

0.38

0.40

0.42

0.44

0.46

0.34 0.36 0.38 0.40 0.42 0.44

X-COORDINATE

Y-COORDINATE

4500K

0.32

0.34

0.36

0.38

0.40

0.42

0.44

0.46

0.48

0.38 0.40 0.42 0.44 0.46 0.48 0.50

X-COORDINATE

Y-COORDINATE

3050K 2850K

3500K 3250K

2700K

Q0 P0

BLACK BODY CURVE

5650K

BLACK BODY CURVE

4100K

3800K

3500K

Figure 16. Color bin Structure for Cool White Figure 17. Color bin structure for Warm White

Figure 18. Color bin structure for Neutral White

Color Bin Limits

Cool

White

Color Limits

(Chromaticity Coordinates)

Bin UM x

0.365

0.386

0.367

0.400

0.348

0.385

0.347

0.372

Bin UN x

0.365

0.386

0.362

0.372

0.346

0.359

0.347

0.372

Bin U0 x

0.362

0.372

0.360

0.357

0.344

0.346

0.359

Bin UP x

0.360

0.357

0.342

0.343

0.331

0.344

Bin VM x

0.329

0.357

0.329

0.369

0.348

0.385

0.347

0.372

Bin VN x

0.329

0.345

0.329

0.357

0.347

0.372

0.346

0.359

Bin V0 x

0.329

0.331

0.329

0.345

0.346

0.359

0.344

Bin VP x

0.329

0.331

0.344

0.343

0.331

0.329

0.320

Bin WM x

0.329

0.369

0.329

0.357

0.315

0.344

0.314

0.355

Bin WN x

0.329

0.345

0.316

0.333

0.315

0.344

0.329

0.357

Bin W0 x

0.329

0.345

0.329

0.331

0.317

0.320

0.316

0.333

Bin WP x

0.329

0.331

0.329

0.320

0.318

0.310

0.317

0.320

Bin WQ x

0.329

0.320

0.329

0.310

0.319

0.300

0.318

0.310

Bin XM x

0.301

0.342

0.314

0.355

0.315

0.344

0.303

0.333

Bin XN x

0.305

0.322

0.303

0.333

0.315

0.344

0.316

0.333

Bin X0 x

0.308

0.311

0.305

0.322

0.316

0.333

0.317

0.320

Bin XP x

0.308

0.311

0.317

0.320

0.319

0.300

0.311

0.293

Bin YO x

0.308

0.311

0.283

0.284

0.274

0.301

0.303

0.333

Bin YA x

0.308

0.311

0.293

0.290

0.270

0.283

0.284

Tolerance: ±0.01

Warm

White

Color Limits

(Chromaticity Coordinates)

Bin MM x

0.471

0.451

0.460

0.430

0.473

0.432

0.486

0.455

Bin M1 x

0.460

0.430

0.453

0.416

0.467

0.419

0.473

0.432

Bin M0 x

0.453

0.416

0.444

0.399

0.459

0.403

0.467

0.419

Bin MA x

0.459

0.403

0.444

0.399

0.436

0.384

0.451

0.389

Bin NM x

0.454

0.446

0.444

0.426

0.460

0.430

0.471

0.451

Bin N1 x

0.444

0.426

0.438

0.412

0.453

0.416

0.460

0.430

Bin N0 x

0.438

0.412

0.429

0.394

0.444

0.399

0.453

0.416

Bin NA x

0.444

0.399

0.429

0.394

0.422

0.379

0.436

0.384

Bin PM x

0.438

0.440

0.430

0.421

0.444

0.426

0.454

0.446

Bin P1 x

0.430

0.421

0.424

0.407

0.438

0.412

0.444

0.426

Bin P0 x

0.424

0.407

0.416

0.389

0.429

0.394

0.438

0.412

Bin PA x

0.429

0.394

0.416

0.389

0.410

0.374

0.422

0.379

Bin QM x

0.421

0.433

0.414

0.430

0.421

0.438

0.440

Bin Q1 x

0.414

0.409

0.400

0.424

0.407

0.430

0.421

Bin Q0 x

0.409

0.400

0.402

0.382

0.416

0.389

0.424

0.407

Bin QA x

0.416

0.389

0.402

0.382

0.396

0.367

0.410

0.374

Tolerance: ±0.01

Neutral

White

Color Limits

(Chromaticity Coordinates)

Bin RM x

0.421

0.433

0.414

0.397

0.406

0.402

0.423

Bin R1 x

0.414

0.409

0.400

0.392

0.391

0.397

0.406

Bin R0 x

0.392

0.391

0.387

0.374

0.402

0.382

0.409

0.400

Bin RA x

0.387

0.374

0.383

0.360

0.396

0.367

0.402

0.382

Bin SM x

0.402

0.423

0.397

0.406

0.382

0.397

0.386

0.413

Bin S1 x

0.397

0.406

0.392

0.391

0.378

0.382

0.397

Bin S0 x

0.392

0.391

0.387

0.374

0.366

0.378

0.382

Bin SA x

0.387

0.374

0.383

0.360

0.370

0.351

0.374

0.366

Bin TM x

0.386

0.413

0.382

0.397

0.365

0.386

0.367

0.400

Bin TN x

0.382

0.397

0.378

0.382

0.362

0.372

0.365

0.386

Bin T0 x

0.378

0.382

0.374

0.366

0.360

0.357

0.362

0.372

Bin TP x

0.374

0.366

0.370

0.351

0.357

0.342

0.360

0.357

Tolerance: ±0.01

Example

ASMT-JW32-NUV01

ASMT-JW32-Nxxxx – Cool White, InGaN,

Electrically isolated Heat Sink

X3 = U – Minimum Flux Bin U

X4 = V – Maximum Flux Bin V

X5 = 0 – Full Distribution

X6 = 1 – Tape and Reel Option

Packaging Option [x6]

Selection Option

1 Tape and Reel

Tape and Reel – Option 1

Figure 19. Carrier Tape Dimensions

Notes:

1. Empty component pockets sealed with top cover tape.

2. 250 or 500 pieces per reel.

3. Drawing not to scale.

4. All dimensions are in millimeters.

Figure 20. Reel dimensions

178 ±1

4 ±0.5 5 ±0.5

3 ±0.5 ø21.0 ±0.5

ø10 ø13.1 ±0.5

ø60 ±0.5

13.2 ±.5

16.0 ±.5

4.00 ±.10

8.00 ±.10

12.00 +.30

.10

4.15 ±.10 0.25 ±0.02

2.05 ±.10

8° ø1.5 ±0.25

2.00 ±.05

5.50 ±.05

1.75 ±0.01

0.25 ±0.02

2.01 ±0.1

ø1.5 ±0.1

5°

5.25 ±.10

DISCLAIMER: Avago’s products and software are not specically designed, manufactured or authorized for sale

as parts, components or assemblies for the planning, construction, maintenance or direct operation of a nuclear

facility or for use in medical devices or applications. Customer is solely responsible, and waives all rights to

make claims against avago or its suppliers, for all loss, damage, expense or liability in connection with such use.

For product information and a complete list of distributors, please go to our web site: www.avagotech.com

Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies in the United States and other countries.

AV02-2428EN - August 25, 2011

CATHODE SIDE

USER FEED DIRECTION

PRINTED LABEL

Figure 21. Reeling Orientation